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Peroxisome proliferator-activated receptors (PPARs) activation leading to reproductive toxicity in rodents Małgorzata Nepelska www.jrc.ec.europa.eu Adverse Outcome Pathways: From Research to Regulation September 3-5, 2014 Serving society Stimulating innovation Supporting legislation DISCLAIMER: This presentation and its contents do not constitute an official position of the European Commission or any of its services. Neither the European Commission nor any person acting on behalf of the Commission is responsible for the use which might be made of this presentation or its contents At the beginning We had an AIM To develop a strategy for building a MoA based chemical category chemical structure f( )= f(MoA)= toxicity How? 2 Building MoA-based chemical category for toxicity prediction STEP 1. Chose endocrine active, data rich chemicals STEP 2. MoA matrix display of experimental data MIE Phthalates ER DEP DiBP DPP DCHP DHP DINP DIDP 0 1 0 0 0 0 0 0 1 DnOP BBP DprP MEHP DEHP / PPAR KE AR AhR Sertoli cells spermato genesis 1 1 1 1 1 1 1 1 1 1 1 1 0 / 0 0 1 1 1 1 0 1 Leydig cells 1 1 1 1 1 AO Decreased testosterone stereodo genesis 1 1 1 1 1 1 0 0 1 1 1 1 1 0 oestrus cycle 1 0 1 1 1 / 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 Male Decreased Sperm reproductive parameters AGD tract 0 1 1 1 1 0 / 0 1 1 1 1 / 1 1 1 1 1 / 1 1 1 1 0 1 1 1 1 / 0 1 1 1 1 STEP 3. Mechanistic "blueprint" of phthalates STEP 4. Search for mechanistic analogues (other chemicals that have similar MoA) 3 PPAR activation leading to reproductive toxicity in rodents MIE KE Adverse Outcome AOP-linked chemical initiators PPAR activation cholesterol transport Hormone synthesis Hormone levels Reproductive toxicity 4 MIE PPARs peroxisome proliferator-activated receptors family comprises the types α, γ and β/δ are nuclear receptor superfamily of transcription factors that respond to specific ligands regulate lipid and carbohydrate metabolism embryonic and foetal development cholesterol uptake and transport represent a potential molecular link between reproductive function and carbohydrate and lipid metabolism Growth factors Nutrients Fatty acids Xenobiotics Endocrine disruptors PPARα,γ β/δ regulated genes vascular functions embryonic and foetal development intracellular trafficking of lipids Lipids and carbohydrates metabolism inflammatory responses 5 MIE MIE PPAR activation: evidence Chemical initiator In vitro binding in vitro transactivation DEHP - + MEHP + + BBP +/- DBP +/- Bisphenol A Butylparaben - + + Knock-out/inhibition/increased expression Experiments with PPARα-null mice indicate involvement of the receptor in reproductive toxicity of phthalates Inhibition studies To be verified To be verified + Increased expression PPARγ + Increased expression PPARγ 6 KE Altered steroidogenic pathway pregnenolone 3 β -HSD-III progesterone P450scc cholesterol Chemical initiator cholesterol StAR TSPO androstenedione aromatase estrone PPAR 17β-HSD IV testosterone binding&activation estradiol aromatase KE KE AO Chemical Initiator DEHP BBP DBP Bisphenol A Butyl paraben Decreased testosterone levels Malformation of reproductive organs + (Howdeshell et al., 2008) + (Gray et al., 2000) (Parks, 2000) + (Howdeshell et al., 2008) + (Gray et al., 2000) (Nagao et al., 2000) + (Howdeshell et al., 2008) (Barlow et al., 2003) (Mylchreest, 2000) + (Barlow et al., 2003) (Mylchreest, 2000) + (Tanaka et al., 2006) (Nakamura et al., 2010) (Talsness et al., 2000) +/(Takagi et al., 2004) (Kobayashi et al., 2002) (Talsness et al., 2000) (Tinwell et al. 2002) + (Zhang et al., 2014) + (Zhang et al., 2014) + effect present / no change ? no information *testosterone production Testicular toxicity + (Kwack et al., 2009) + (Gray et al., 2000) + (Mylchreest, 2000) + (Talsness et al., 2000) + (Oishi et al., 2001) 8 PPAR activation leading to reproductive toxicity in rodents KE MIE PPAR activation cholesterol transport to mitochondria Adverse Outcome Hormone synthesis Hormone levels Reproductive toxicity Altered oestrus cycle Decreased ovary weight Malformation of reproductive organs Decreased AGD Hypospadias 9 PPAR activation leading to reproductive toxicity in rodents cholesterol transport to mitochondria AOP 1 PPAR activation cholesterol transport to mitochondria testosterone synthesis AOP 2 PPAR activation cholesterol transport to mitochondria AOP 3 PPAR activation cholesterol transport to mitochondria testosterone synthesis Estradiol synthesis Estradiol synthesis Hormone levels Reproductive toxicity Hormone levels Reproductive malformations Hormone levels Altered estrus cycle Hormone levels Testicular toxicity adult prental PPAR activation 10 PPAR activation leading to reproductive toxicity in rodents PPARα/γ PPAR activation activation Estradiol synthesis Hormone levels Malformations Reproductive organs Hormone levels Altered estrus cycle Hormone levels Testicular toxicity adult cholesterol transport to mitochondria prental testosterone synthesis testosterone synthesis 11 PPARα activation leading to reproductive tract malformations in males upon in utero exposure AOP-linked chemical initiators KE MIE PPARα activation cholesterol transport to mitochondria Adverse Outcome Testosterone synthesis Testosterone levels Malformation Reproductive organs Decreased AGD Hypospadias 12 PPARα activation leading to reproductive tract malformations in males upon in utero exposure Key Events Molecular Initiating Event: Binding to and activation to PPARα Key Event: Impaired steroidogenesis Experimental Support Strength of Evidence DEHP/MEHP, BBP, DBP binding to PPARα in vitro, in silico PPARα transactivation by DEHP/MEHP, BBP, DBP, butylparaben Experiments with PPARα-null mice indicate involvement of the receptor in reproductive toxicity of phthalates Moderate Impaired transport of cholesterol to mitochondria decreased gene expression of SR-B1, TSPO (PBR), StAR decreased gene expression of P450scc, 3β-HSD, 17β-HSD Moderate Key Event: Decreased testosterone levels Decreased testosterone levels measured in plasma Decreased testosterone production measured ex-vivo Adverse Outcomes: Reproductive tract malformations DEHP, DBP,BBP, butylparaben, decreased AGD DEHP, DBP,BBP, Hypospadias Weak Moderate Strong Strong Strong 13 Challenges for these AOPs Data mining Literature organisation and structural capturing of the biological events 14 Challenges for these AOPs cd. Data mining Literature organisation and structural capturing of the biological events Quality and quantity of data in literature (PPAR α or/and γ), dose levels, more mechanisms involved Relevance for humans Mode of action PPAR expression Steroidogenesis is conserved Adversity TDS- Testicular Dysgenesis Syndrome in humans 15 Future plans To insert quantitative data into the OECD AOP-Knowledge Base To further substantiate AOP with evidence from other chemicals To develop other pathways interconnected with the current ones aiming at AOP network To further develop the database for capturing the literature and provide a template for structured data gathering 16 Acknowledgment Brigitte Landesmann Edward Carney Sharon Munn Andrew Worth Julien Burton Alfonso Lostia Thank you for coming questions 17